Refiner and method for refining fibrous material
A refiner (1, 18, 19) for refining fibrous material has at least one first refining surface (11) and at least one second refining surface (4), which are arranged at least partly substantially opposite to one another in such a manner that a refiner chamber (12) is formed between them, to which the material to be defibrated is arranged to be fed. The first refining surface or the second refining surface has openings formed through them and through which fibrous material to be refined can be fed into the refiner chamber or through which refined fibrous material can be removed from the refiner chamber. In addition, a method for refining fibrous material, a refining surface of a refiner and a blade segment for a refiner.
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This application is a U.S. national stage application of International App. No. PCT/FI2009/050545, filed Jun. 18, 2009, the disclosure of which is incorporated by reference herein, and claims priority on Finnish App. No. 20080414, filed Jun. 19, 2008, the disclosure of which is incorporated by reference herein.
STATEMENT AS TO RIGHTS TO INVENTIONS MADE UNDER FEDERALLY SPONSORED RESEARCH AND DEVELOPMENTNot applicable.
BACKGROUND OF THE INVENTIONThe invention relates to a refiner for refining fibrous material, the refiner comprising at least one first refining surface and at least one second refining surface, which are arranged at least partly substantially opposite to one another in such a manner that a refiner chamber is formed between them, to which the material to be defibrated is arranged to be fed, and at least either the first refining surface or the second refining surface in the refiner is arranged to move with respect to the opposite refining surface, and at least either the first refining surface or the second refining surface in the refiner comprises blade bars and blade grooves therebetween.
The invention further relates to a method for refining fibrous material, the method comprising refining fibrous material with a refiner which comprises at least one first refining surface and at least one second refining surface, which are arranged at least partly substantially opposite to one another in such a manner that a refiner chamber is formed between them, to which material to be defibrated is fed, and at least either the first refining surface or the second refining surface in the refiner is arranged to move with respect to the opposite refining surface, and at least either the first refining surface or the second refining surface in the refiner comprises blade bars and blade grooves therebetween.
The invention further relates to a refining surface for a refiner intended for refining fibrous material, the refiner comprising at least one first refining surface and at least one second refining surface, which are arranged at least partly substantially opposite to one another in such a manner that a refiner chamber is formed between them, to which the material to be defibrated is arranged to be fed, and at least either the first refining surface or the second refining surface in the refiner is arranged to move with respect to the opposite refining surface, and at least either the first refining surface or the second refining surface in the refiner comprises blade bars and blade grooves therebetween.
The invention further relates to a blade segment for a refiner intended for refining fibrous material, the blade segment comprising a refining surface with blade bars and blade grooves therebetween. Refiners for treating fibrous material typically comprise two, possibly even more refining surfaces substantially opposite to one another, between which there is a refiner chamber to which the fibrous material to be refined is fed. At least one of the refining surfaces is arranged to move with respect to the opposite refining surface. The refining surface may be one integral structure or it may consist of a plurality of refining surface segments arranged adjacent to one another, whereby the refining surfaces of individual refining surface segments form one uniform refining surface. The refining surfaces are typically provided with specific blade bars, i.e. bars, and blade grooves, i.e. grooves, therebetween, fibrous material being refined between the blade bars of the opposite refining surfaces and both the material to be refined and the already refined material being able to move in the blade grooves between the blade bars on the refining surface. On the other hand, the refining surface may comprise protrusions and recesses between the protrusions. The blade bars and blade grooves of the refining surfaces, or the protrusions and recesses of the refining surfaces, may be made of the basic material of the refiner blade or a separate material. The protrusions may also be formed of ceramic grits attached to the refining surface by previously known methods. The refining surfaces, i.e. the blade surfaces, may also be formed of separate lamellae arranged adjacent to or at a distance from one another and fixed to form a refining surface. The refining surface may also comprise a large number of small protrusions and recesses therebetween, in which case the refiner operates by a grinding principle.
The refiner chamber is a space which is formed between the refining surfaces of a stator and a rotor and where the refining takes place. The refining is caused by mutual pressing and motion of the refining surfaces as a result of frictional forces between the refining surfaces and the material to be refined and, on the other hand, due to frictional forces inside the material to be refined. The surface area between the refining surfaces of the rotor and the stator is the refining area, by which the refining between the refining surfaces of the rotor and the stator takes place in the refiner chamber. The shortest distance between the refining surfaces of the rotor and the stator in the region of the refining area is the blade gap.
To increase the production of refiners, it is important to guide the fibrous material to be refined efficiently between the opposite refining surfaces for refining. At the same time, it is naturally important to enable the removal of sufficiently refined material from between the refining surfaces in such a manner that the refined material does not block up the refiner chamber between the refining surfaces and thus weaken the production of the refiner. Particularly in refining surfaces comprising blade bars and blade grooves therebetween, the guiding of fibrous material between the opposite blade bars has been made more effective by providing o special dams on the bottom of the grooves, the dams forcing the material to be refined to move away from the bottom of the grooves to the space between the opposite refining surfaces. However, the effect of the dams is local and does not substantially benefit the whole area of the refining surface. The dams also diminish the hydraulic capacity of the refining surface considerably. Also by changing the height of the blade groove bottom and/or the volume of the blade groove it is possible to try to force the flow of material to be refined to move between the opposite refining surfaces and thus to make the refining more effective. In addition, by tilting the blade bars, it is possible to affect the flow of material to be refined and thus force the material to be refined to pass between the opposite blade bars.
A problem with all these solutions is, however, that they do not significantly improve the guiding of the material to be refined into the refiner chamber without simultaneously weakening the production capacity of the refiner.
SUMMARY OF THE INVENTIONIt is an object of the present invention to provide a new type of refiner and a method, wherein the flow of material to be refined can be guided more efficiently into a refiner chamber between opposite refining surfaces and the operation of the refiner can thus be made more effective. The refiner of the invention is characterized in that the first refining surface comprises first openings formed through the first refining surface and through which fibrous material to be refined is arranged to be fed into the refiner chamber of the refiner, or that the second refining surface comprises second openings formed through the second refining surface and through which fibrous material to be refined is arranged to be fed into the refiner chamber of the refiner, or that the first refining surface comprises first openings formed through the first refining surface and through which refined fibrous material is arranged to be removed from the refiner chamber of the refiner, or that the second refining surface comprises second openings formed through the second refining surface and through which refined fibrous material is arranged to be removed from the refiner chamber of the refiner, and that the ratio of the surface area of said openings to the total area of the refining surface ranges from 5 to 70%, more preferably from 7 to 55%, and most preferably from 10 to 40%.
The method of the invention is characterized by feeding fibrous material to be refined through openings formed through the first refining surface into the refiner chamber between the refining surfaces of the refiner, or by feeding fibrous material to be refined through openings formed through the second refining surface into the refiner chamber between the refining surfaces of the refiner, or by removing refined fibrous material through the openings formed through the first refining surface from the refiner chamber or the refiner, or by removing refined fibrous material through the openings formed through the second refining surface from the refiner chamber of the refiner, the ratio of the surface area of the openings to the total area of the refining surface ranging from 5 to 70%, more preferably from 7 to 55%, and most preferably 10 to 40%.
The refining surface of the invention is characterized in that the refining surface comprises openings formed through the refining surface and through which fibrous material to be refined may be arranged to be fed into the refiner chamber of the refiner or removed from the refiner chamber of the refiner, and that the ratio of the surface area of said openings to the total area of the refining surface ranges from 5 to 70%, more preferably from 7 to 55%, and most preferably from 10 to 40%.
The blade segment of the invention is characterized in that the refining surface of the blade segment comprises openings formed through the refining surface, the ratio of the surface area of the openings to the total area of the refining surface ranging from 5 to 70%, more preferably from 7 to 55%, and most preferably from 10 to 40%.
The refiner for refining fibrous material comprises at least one first refining surface and at least one second refining surface, which are arranged at least partly substantially opposite to one another in such a manner that a refiner chamber is formed between them, to which the material to be defibrated is arranged to be fed. Further in the refiner, at least either the first refining surface or the second refining surface is arranged to move with respect to the opposite refining surface and at least either the first refining surface or the second refining surface comprises blade bars and blade grooves therebetween. The first refining surface of the refiner further comprises first openings formed through the first refining surface and through which fibrous material to be refined is arranged to be fed into the refiner chamber of the refiner, or the second refining surface of the refiner comprises second openings formed through the second refining surface and through which fibrous material to be refined is arranged to be fed into the refiner chamber of the refiner, or that the first refining surface comprises first openings formed through the first refining surface and through which refined fibrous material is arranged to be removed from the refiner chamber of the refiner, or that the second refining surface comprises second openings formed through the second refining surface and through which refined fibrous material is arranged to be removed from the refiner chamber of the refiner. Furthermore, the ratio of the surface area of said openings to the total area of the refining surface ranges from 5 to 70%, more preferably from 7 to 55%, and most preferably from 10 to 40%.
Thus, the refiner chamber is a space which is formed between the refining surfaces of a rotor and a stator and where the refining takes place. The surface area formed between the refining surfaces of the rotor and the stator is the refining area, by which the refining between the refining surfaces of the rotor and the stator takes place in the refiner chamber. In the context of this specification and the claims, the term “blade bar” also refers to the previously mentioned protrusions and the term “blade groove” also refers to the recesses between said protrusions.
The refining surface of the refiner's rotor or stator is provided with openings, when the distance between the edge of an opening and the edge of the closest, second opening, i.e. the measurement of the space without openings, is under 200 mm. More preferably the distance from the edge of an opening to the edge of the closest, second opening is under 100 mm. Most preferably the distance from the edge of an opening to the edge of the closest, second opening is under 50 mm.
If there are openings only on one refining surface, it is advantageous for both the production and the refining result of the refined fiber suspension to provide openings close to one another, which results in a high yield and a good quality of a refined fiber suspension, since material to be refined can be fed efficiently into the refiner chamber and distributed evenly in the refiner chamber. If there are openings on both refining surfaces defining the refiner chamber, a good yield is primarily affected by the total area of the openings.
However, the refining result improves when the openings are not located too densely, which means that the material to be refined stays in the refiner chamber a longer time before it is discharged and undergoes a refining treatment resulting in a good pulp quality. On the other hand, when openings are densely located, the material to be refined is efficiently guided directly to each blade bar for refining, and the refiner blades are utilized efficiently for refining treatment. When a refiner with densely located openings is used with a great flow-through, the production is high and refining is relatively efficient. By reducing the flow-through, or production, the refining time can be made longer, and also a blade with densely located openings provides a sufficient residence time in the refiner chamber and a good pulp quality.
By feeding fibrous material to be refined through the openings formed through either the first refining surface or the second refining surface, it is possible to feed fibrous material into the refiner chamber more efficiently and more evenly than before, so that the distribution of the material to be refined in the refiner chamber is more even than previously. This makes the refining more effective and thus increases the capacity of the refiner. Alternatively, by removing refined fibrous material through the openings formed through either the first refining surface or the second refining surface away from the refiner chamber, it is possible to remove refined fibrous material from the refiner chamber more efficiently, and the risk of blocking up the refiner decreases. This also makes the refining more effective and thus increases the capacity of the refiner. At the same time, the efficiency of the refiner or the refining compared to the previously known solutions may be further improved as the ratio of the surface area of said openings to the total area of the refining surface ranges from 5 to 70%, more preferably from 7 to 55%, and most preferably 10 to 40%.
According to an embodiment of the invention, the first refining surface comprises openings formed through the first refining surface and through which fibrous material to be refined is arranged to be fed into the refiner chamber of the refiner, and the second refining surface comprises openings provided through the second refining surface and through which fibrous material refined in the refiner is arranged to be removed from the refiner chamber.
According to a second embodiment of the invention, the second refining surface comprises openings formed through the second refining surface and through which fibrous material to be refined is arranged to be fed into the refiner chamber of the refiner, and the first refining surface comprises openings formed through the first refining surface and through which fibrous material refined in the refiner is arranged to be removed from the refiner chamber.
By feeding fibrous material to be refined through the first refining surface into the refiner chamber and removing the already refined fibrous material from the refiner chamber through the second refining surface essentially opposite to the first refining surface or vice versa, it is possible to feed fibrous material into the refiner chamber more efficiently and more evenly than before. As a result, the distribution of the material to be refined in the refiner chamber is more even than previously, which also increases the efficiency and thus capacity of the refiner. While material to be refined is removed from the refiner chamber through the openings formed through either the first refining surface or the second refining surface, refined material can be efficiently removed from the refiner chamber. This reduces the risk of blocking up the refining surface, which in turn further increases the efficiency and thus capacity of the refiner.
According to a third embodiment of the invention, the material to be refined is arranged to be fed into the refiner chamber through the openings that are only provided in either the first refining surface or the second refining surface.
Some embodiments of the invention will be described in more detail in the attached drawings.
In the figures, some embodiments of the invention are shown simplified for the sake of clarity. Similar parts are marked with the same reference numbers in the figures.
DESCRIPTION OF THE PREFERRED EMBODIMENTSIn the embodiment of
Since the space between the rotor 9 and the frame 2 of the refiner is not fully closed, part of the fibrous material to be fed into the refiner 1 according to
By feeding fibrous material to be refined through the openings formed through the first refining surface, i.e. the refining surface of the rotor, into the refiner chamber, it is possible to feed fibrous material into the refiner chamber more efficiently and more evenly than before, so that the distribution of the material to be refined in the refiner chamber is more even than previously. This makes the refining more effective and thus increases the capacity of the refiner. The efficiency of the refiner or the refining compared to the previously known solutions can be further improved when the ratio of the surface area of said openings to the total area of the refining surface ranges from 5 to 70%, more preferably from 7 to 55%, and most preferably 10 to 40%, for instance from 16 to 17%. Also, the efficiency of the refiner compared to the known solutions may be further improved when said openings are arranged on said refining surface to cover, for instance, at least 60% of the refining area. In addition, as at least either the movable refining surface or the fixed refining surface comprises blade bars and blade grooves therebetween, it is possible to intensify the refining effect directed at the fibers with respect to refiners in which the refining surfaces do not comprise blade bars or blade grooves between them.
The fibrous material to be refined is fed into the refiner 18 via a feed opening 13 or feed channel in a manner shown schematically by arrow C. The majority of the fibrous material fed into the refiner 18 passes into the open space 21 under the refining surface 11 of the rotor 9, as shown by arrows D, and from there through openings 14 formed through the refining surface 11 of the rotor 9 into the refiner chamber 12, where fibrous material is refined. The openings 14, through which fibrous material to be refined can be fed into the refiner chamber 12, may be arranged on the refining surface 11 to cover, for instance, at least 60% of the refining area, preferably at least 80% of the refining area, and most preferably to cover the entire refining area. However, said openings may also be arranged on the refining surface 11 to cover less than 60% of the refining area.
Since the space between the rotor 9 and the frame 2 of the refiner 18 is not fully closed, part of the fibrous material to be fed into the refiner 18 according to
In the embodiment of
The openings 15, through which fibrous material to be refined can be fed into the refiner chamber 12, may be arranged on the refining surface 4 to cover, for instance, at least 60%, preferably at least 80% of the refining area, and most preferably to cover the entire refining area. However, said openings 15 may also be arranged on the refining surface 11 to cover less than 60% of the refining area. The ratio of the surface area of said openings 15 to the total area of the refining surface 4 can be arranged to range from 5 to 70%, more preferably from 7 to 55%, and most preferably from 10 to 40%, for instance from 16 to 17%. Refined material exits the refiner chamber 12 from its second edge 23 and further out of the refiner 18 via a discharge opening 17 or discharge channel, as shown schematically by arrows E. In the embodiment of
In the embodiment of
By alternatively feeding fibrous material to be refined through the openings formed through the second refining surface, i.e. refining surface of the stator, into the refiner chamber, it is also then possible to feed fibrous material into the refiner chamber more efficiently and more evenly than before, so that the distribution of the material to be refined in the refiner chamber is more even than previously. The efficiency of the refiner or the refining compared to the previously known solutions may be further improved when the ratio of the surface area of said openings to the total area of the refining surface ranges from 5 to 70%, more preferably from 7 to 55%, and most preferably 10 to 40%, for instance from 16 to 17%. At the same time, the efficiency of the refiner compared to the known solutions may be further improved when said openings are arranged on said refining surface to cover, for instance, at least 60% of the refining area.
In the embodiment of
The openings 14, through which fibrous material to be refined can be fed into the refiner chamber 12, may be arranged on the refining surface 11 to cover at least 60%, preferably at least 80% of the refining area, and most preferably to cover the entire refining area. The ratio of the surface area of the openings 14 to the total area of the refining surface 11 can be arranged to range from 5 to 70%, more preferably from 7 to 55%, and most preferably from 10 to 40%, for instance from 16 to 17%. In the embodiment of
The fibrous material to be refined is fed into the refiner 1 via a feed opening 13 or feed channel in a manner shown schematically by arrow C. The majority of the fibrous material fed into the refiner 1 passes into an open space 21 under or behind the refining surface 11 of the rotor 9, as shown by arrows D, and from there through openings 14 formed through the refining surface 11 of the rotor 9 into the refiner chamber 12. The refined material is able to pass from the refiner chamber 12 through the openings 15 in the refining surface 4 of the stator 3 into the intermediate space 16 between the refiner 1 frame 2 and the stator 3, from where the refined material is removed via the discharge channel 17 or discharge opening out of the refiner 1, as shown schematically by arrow E. Since the space between the rotor 9 and the frame 2 of the refiner 1 is not fully closed, part of the fibrous material to be fed into the refiner 1 according to
In the embodiment of
The openings 14, through which fibrous material to be refined can be fed into the refiner chamber 12, or the openings 15, through which refined fibrous material can be removed from the refiner chamber 12, may be arranged on the refining surfaces 4 and 11 to cover, for instance, at least 60%, preferably at least 80% of the refining area, and most preferably to cover the entire refining area. The ratio of the surface area of the openings to the total area of the refining surface can be arranged to range from 5 to 70%, more preferably from 7 to 55%, and most preferably from 10 to 40%, for instance from 16 to 17%. Compared to
In the embodiment of
In the embodiment of
In the embodiment of
Further in the embodiment of
In the cylindrical refiner 18 of
The fibrous material to be refined is fed into the refiner 19 via a feed opening 13 or feed channel in a manner shown schematically by arrow C. The fibrous material fed into the refiner 19 passes into an open space 21 behind the refining surface 11 of the rotor 9, as shown by arrows D, and from there through openings 14 formed through the refining surface 11 of the rotor 9 into the refiner chamber 12, as shown by arrows D. The refined material is able to pass through the openings 15 in the refining surface 4 of the stator 3 into the intermediate space 16 between the refiner 19 frame 2 and the stator 3, from where the refined material is removed via a discharge channel 17 or discharge opening out of the refiner 19, as shown schematically by arrow E. Refined material may also exit the refiner chamber 12 from the outer circumference of the refining surfaces 4, 11, from where there is also a connection to the intermediate space 16 between the refiner 19 frame 2 and the stator 3. Transfer of material to be refined and fed into the refiner from the feed opening 13 directly to the refiner chamber 12 is prevented by a protective structure 20.
In the embodiment of
The openings 14, through which fibrous material to be refined can be fed into the refiner chamber 12, are arranged on the refining surface 11 to cover at least 60%, preferably at least 80% of the refining area, and most preferably to cover the entire refining area.
As was described above in connection with cone refiners and cylindrical refiners, in disc refiners, too, the feeding of fibrous material into the disc refiner 19 may be arranged in such a manner that fibrous material to be refined is fed into the intermediate space 16, from where it passes through the openings 15 in the refining surface 4 of the stator 3 into the refiner chamber 12. The refined material may in turn be removed from the refiner chamber 12 through the openings 14 in the refining surface 11 of the rotor 9. In this case, the feed opening 13 or feed channel 13 for feeding fibrous material to be refined into the refiner 19 and the discharge channel 17 or discharge opening for removing the refined fibrous material from the refiner 19 change places with one another.
When the refiner of
In addition to the examples shown in
In the refiner according to the solution, fibrous material to be refined is fed into the refiner chamber at least mainly through the openings in either the refining surface of the movable refiner element or the refining surface of the fixed refiner element, or alternatively the refined fibrous material is removed from the refiner chamber mainly through the openings in either the refining surface of the movable refiner element or the refining surface of the fixed refiner element. However, it is also possible that all the refiner types described above only comprise movable refining surfaces and no fixed refining surfaces at all, in which case the second movable refining surface thus constitutes the second refining surface of the refiner. Thus, the opposite refining surfaces in a disc refiner, for instance, are rotated separately by a shaft in opposite directions.
By feeding fibrous material to be refined through the refining surface, the material to be refined can be fed evenly into the refiner chamber. It is also ensured that the material to be refined flows from the feed of material to its discharge via the refiner chamber, which means that a greater amount of fibers will be refined than before. By removing refined material through the opposite refining surface, it is possible to diminish the flow of the material to be refined and of the refined material in the direction of the refining surface, which reduces pressure losses in the refiner and increases production. By means of the feed rate of material to be refined and the speed of the movable refining surface, it is possible to influence the degree of refining, i.e. how much refining the fibers are subjected to. By feeding material to be refined through either the movable or fixed refining surface and simultaneously removing refined material through the opposite refining surface, the most significant advantages are achieved for the refiner and the entire refining operation.
The solution also allows the flow of material to be defibrated to decrease on the plane of the refining surface or parallel to its tangent, and the design of refining surfaces may thus be mainly focused on optimizing the refining effect directed at fibers, since the significance of the refining surface in the transport of material to be refined and of the refined material is not so great. As a result, transfer of material on the refining surface may be arranged with fewer pressure losses and in more spacious feed and discharge channels of the refiner, thus reducing the power losses of the refiner. If all fibrous material fed into the refiner is to pass through the refining surface into the refiner chamber, cone and cylindrical refiners may, similarly to disc refiners of
The openings 15 formed through the refining surface 4 of the stator 3 and the openings 14 formed through the refining surface 11 of the rotor 9 may be formed through the blade bars 5 on the refining surface only, through the blade grooves 6 in the refining surface only, or through both the blade bars 5 and the blade grooves 6 in the refining surface.
The shape, size and direction of the openings 14 and 15 in the refining surfaces as well as the ratio of their surface area to the total area of the refining surface may vary in many different ways. In the embodiment of
The elongated openings 14 may thus be arranged substantially parallel to the central axis of the refining surface, as in
When the movable refining surface is arranged as the inner refining surface, which is possible with a cylindrical and cone refiner, a pumping effect is produced in the material flow by centrifugal force, which improves the transfer of the material to be refined into the refiner chamber. The pumping effect may be further increased or decreased by directing the opening or the structure preceding the opening or by utilizing a flow-related design, because the walls of the opening in the movable refining surface that push the material flow cause a force resultant in the material flow, which acts parallel to the normal of the wall. When the movable refining surface is arranged as the outer refining surface, the flow through the opening can be influenced in a corresponding manner by directing the opening. Also in the case of a disc refiner, the flow through the opening in the movable refining surface may also be intensified by means of centrifugal force so that the opening is directed at least to some extent in the direction of the radius. A fixed refining surface does not produce a flow by means of centrifugal force, but the flow through the fixed refining surface can be reduced to a small or large extent by directing the opening by means of forces transmitted to the material flow via the walls of the opening.
In some cases, the features described in this application may be used as such, regardless of other features. On the other hand, the features described in this application may also be combined to provide various combinations as necessary. The drawings and the related description are only intended to illustrate the idea of the invention. The invention may vary in its details within the scope of the claims. In all embodiments shown in the figures the refining surfaces of the refiners comprise blade bars and blade grooves therebetween for forming a refining surface, but it is naturally obvious that the refining surfaces of a refiner may also be provided in such a manner that, for instance, only one refining surface comprises blade bars and blade grooves therebetween. It is also obvious that, since the refining surface comprises blade bars and blade grooves therebetween, the upper surface of the blade bars, i.e. the surface facing towards the opposite refining surface, may comprise smaller blade bars and blade grooves therebetween. It is also obvious that the first edge of the refiner chamber shown in the figures may, if desired, be defined as the second edge and the second edge may be defined as the first edge. It is also obvious that the blade bars and the blade grooves may be formed in a variety of ways in their longitudinal direction or direction of travel, for example such that the blade bars and the blade grooves therebetween are straight or curved.
Claims
1. A refiner for refining fibrous material, the refiner comprising:
- at least one refining element forming a shell having a back side, a shell body and a front side, the front side defining a first refining surface comprising portions of the shell body which extend away from the shell body forming outwardly extending blade bars which terminate at the first refining surface, the blade bars defining blade grooves therebetween;
- wherein the refining element has portions forming a regular geometrically distributed pattern of a multiplicity of first openings passing though the shell body from the back side to the refiner surface so that at least most of the first openings cut through at least one blade bar, and substantially every blade bar is cut by said openings a plurality of times;
- at least one second refining surface which is arranged at least partly substantially opposite to the first refining surface to define a refining area, and a refiner chamber therebetween;
- wherein the first refining surface and the second refining surface are arranged to provide for movement between the first refining surface and the second refining surface;
- wherein the first refining surface defines a total refining area and wherein the first refining surface first openings are ones through which fibrous material to be refined is arranged to be fed into or removed from the refiner chamber of the refiner, the first openings defining a first opening area; and
- wherein a ratio is defined between the first opening area composed of said first openings and the total refining area of the first refining surface, which ratio is from 10% to 40%.
2. The refiner of claim 1 wherein the second refining surface defines a second refining area and wherein the second refining surface has second openings formed through the second refining surface through which fibrous material to be refined is arranged to be fed into or removed from the refiner chamber.
3. The refiner of claim 2, wherein the material to be refined is arranged to be fed into the refiner chamber only through the first openings in the first refining surface or only through the second openings in the second refiner surface.
4. The refiner of claim 2, wherein the first openings formed through the first refining surface are arranged only to feed fibrous material into the refiner chamber of the refiner, and wherein the second openings formed through the second refining surface are arranged only to remove fibrous material from the refiner chamber.
5. The refiner of claim 1 wherein one of the first refining surface and the second refining surface is arranged to form a movable refining surface of the refiner, and the other a fixed refining surface of the refiner.
6. The refiner of claim 2, wherein said first openings in the first refiner surface are arranged on the first refiner surface to cover at least 60% of the total area of the first refining surface, and said second openings in the second refiner surface are arranged on the second refiner surface to cover at least 60% of the total area of the second refining surface.
7. The refiner of claim 6, wherein said first openings in the first refiner surface are arranged on the first refiner surface to cover at least 80% of the total area of the first refining surface, and said second openings in the second refiner surface are arranged on the second refiner surface to cover at least 80% of the total area of the second refining surface.
8. The refiner of claim 1 wherein the first openings in the first refining surface have a shape selected from the group consisting of a round, oval, polygonal or elongated shape.
9. The refiner of claim 1 wherein the refiner is selected from the group consisting of: a cone refiner, a cylindrical refiner, and a disc refiner.
10. A method for refining fibrous material comprising the steps of:
- refining fibrous material by passing said fibrous material into a refiner chamber formed between a first refining element and a second refining element, the at least one refining element forming a shell having a back side, a shell body and a front side, the front side defining a first refining surface comprising portions of the shell body which extend away from the shell body forming outwardly extending blade bars which terminate at the first refining surface, the blade bars defining blade grooves therebetween, and wherein the refining element has portions forming a regular geometrically distributed pattern of a multiplicity of first openings passing though the shell body from the back side to the first refiner surface so that at least most of the first openings cut through at least one blade bar, and substantially every blade bar is cut by said openings a plurality of times, the second refining element having a second refining surface which is arranged at least partly substantially opposite to the first refining surface;
- defibrating the fibrous material in the refiner chamber with the blade bars with the blade grooves therebetween, which blade bars and grooves being formed on at least the first refining surface, the defibrating of the fibrous material in the refiner chamber taking place by moving at least a selected one of the first refining surface and the second refining surface with respect to the other refining surface;
- wherein the step of defibrating the fibrous material in the chamber formed between the first refining surface and the second refining surface further comprises passing the fibrous material either in through the first openings or out through the first openings in at least the first refining surface, which first openings extend through the first refining surface into the refiner chamber;
- wherein the first refining surface defines a total refining area of the refining surface, and the first openings define a surface area of said first openings; and
- wherein a ratio is formed between the surface area of said first openings and the total refining area of the first refining surface which is from 10% to 40%.
11. The method of claim 10, wherein fibrous material to be refined is fed through the first openings formed through the first refining surface into the refiner chamber between the refining surfaces and refined fibrous material is removed through second openings formed through the second refining surface from the refiner chamber.
12. The method of claim 10 wherein the material to be refined is fed into the refiner chamber only through the first openings in either the first refining surface or second openings in the second refining surface.
13. The method of claim 10, wherein said first openings through which fibrous material to be refined is fed into the refiner chamber of the refiner are arranged on the first refining surface to cover at least 60% of the total refining area.
14. The method of claim 13, wherein said openings through which fibrous material to be refined is fed into the refiner chamber of the refiner are arranged on the first refining surface to cover at least 80% of the total refining area.
15. The method of claim 10 wherein the second refining surface defines a total refining area and wherein said openings through which fibrous material to be refined is removed from the refiner chamber of the refiner are arranged on the second refining surface to cover at least 60% of the total refining area.
16. The method of claim 15 wherein said openings through which fibrous material to be refined is removed from the refiner chamber of the refiner are arranged on the second refining surface to cover at least 80% of the total refining area.
17. A refiner for refining fibrous material comprising:
- at least one refining element forming a shell having a back side, a shell body, and a front side, the front side defining a first refining surface comprising portions of the shell body which extend away from the shell body forming outwardly extending blade bars which terminate at the first refining surface, the blade bars defining blade grooves therebetween;
- wherein the at least one refining element has portions forming a regular geometrically distributed pattern of a multiplicity of first openings passing though the shell body from the back side to the first refining surface so that at least most of the first openings cut through at least one bar, and substantially every bar is cut by said openings a plurality of times;
- at least one second refining surface which is arranged at least partly substantially opposite to the first refining surface to form a refiner chamber therebetween, to which material to be defibrated is arranged to be fed;
- at least a selected one of the first refining surface and the second refining surface in the refiner being arranged to move with respect to the other refining surface;
- wherein the first refining surface has a total refining area, and the first refining surface portions forming the first openings are ones through which fibrous material to be refined may be arranged to be fed into the refiner chamber of the refiner or removed from the refiner chamber of the refiner, the first openings defining a surface area; and
- wherein a ratio is defined of the surface area of said first openings to the total refining area which is from 10% to 40%.
18. The refiner of claim 17 wherein said first openings are arranged on the first refining surface to cover at least 60% of the total refining area.
19. A blade segment for a refiner intended for refining fibrous material, the blade segment comprising
- a shell having a back side, a shell body, and a front side, the front side defining a first refining surface comprising portions of the shell body which extend away from the shell body forming outwardly extending blade bars which terminate at the first refining surface, the blade bars defining blade grooves therebetween;
- wherein the refining surface has portions forming a regular geometrically distributed pattern of a multiplicity of openings passing though the shell body from the back side to the refining surface so that at least most of the openings cut through at least one blade bar, and substantially every blade bar is cut by said openings a plurality of times;
- wherein the openings define a surface area of said openings and the refining surface defines a total refining area; and
- wherein a ratio defined between the surface area of said openings and the total refining area is from 10% to 40%.
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Type: Grant
Filed: Jun 18, 2009
Date of Patent: Aug 20, 2013
Patent Publication Number: 20110089273
Assignee: Metso Paper, Inc. (Helsinki)
Inventors: Kati Lindroos (Lempäälä), Jorma Halla (Valkeakoski), Markku Partanen (Valkeakoski), Kauko Vänni (Nokia)
Primary Examiner: Dana Ross
Assistant Examiner: Chwen-Wei Su
Application Number: 12/999,990
International Classification: B02C 17/00 (20060101); B02C 17/02 (20060101); B02C 13/00 (20060101);